Abstract

A new design method for T-S fuzzy controller which guarantees global asymptotic stability and satisfies a desired performance is proposed in this paper. The method uses the LMI approach to find the common symmetric positive definite matrix P and feedback gains K/sub i/, i=1, 2, ..., r, numerically. The LMIs for the stability criterion which treats P and K/sub i/s as matrix variables is derived from Wang et al.'s (1995) stability criterion. Wang et al.'s stability criterion uses nonlinear MIs since P and K/sub i/s are coupled together. The desired performance is represented as r LMIs which place the closed-loop poles of r local subsystems within the desired region in the s-plane. By solving the stability LMIs and pole placement constraint LMIs simultaneously, the feedback gains K/sub i/s which guarantee global asymptotic stability and satisfy the desired performance are determined. The design method is verified by designing a T-S fuzzy controller for an inverted pendulum with a cart using the proposed method.